KR20220085357A - anti-vibration structure of CNC machine - Google Patents

Abstract

The vibration transition prevention structure of a two-spindle machine tool according to the present invention includes a first spindle and a second spindle arranged symmetrically to each other, a gantry for transferring a material from the first spindle to a second spindle, and the first spindle A first support fixed to the gantry to support the gantry, and a second support fixed to the second spindle to support the gantry.
In addition, it is connected to the first support and comprises a side auxiliary beam fixed to the ground, wherein the first support is connected to the side auxiliary beam, the lower end of the support bracket portion of the upper surface of the bed of the first spindle and spaced apart to form a gap.
In addition, the second support is connected to the second support and may include a side auxiliary beam fixed to the ground, and the second support is connected to the side auxiliary beam with a support bracket at the lower end of the bed portion of the second spindle. It is spaced apart from the upper surface to form a gap.
In addition, the bed portion of the first spindle and the bed portion of the second spindle are spaced apart from each other to form a gap.
The present invention may include a support pad detachably attached to the bottom surface of the support bracket at the lower end of the first support and selectively interposed in the gap between the support bracket and the upper surface of the bed of the first spindle.
The present invention may include a support pad detachably attached to the bottom surface of the support bracket at the lower end of the second support and selectively interposed in the gap between the support bracket and the upper surface of the bed of the second spindle.
The present invention may include a gap plate selectively fitted in a gap between the bed portion of the first spindle and the bed portion of the second spindle, wherein the gap plate includes the bed portion of the first spindle and A plate portion having a thickness thinner than the width of the gap between the bed portions of the second spindle, and formed on the upper end of the plate portion, the thickness of which is greater than the width of the gap between the bed portion of the first spindle and the bed portion of the second spindle is made of a thick locking end.
According to the present invention, since the support for supporting each spindle is connected to the side auxiliary beam, a gap is formed between the support and the bed portion, and since a gap is also formed between the bed portions of both spindles, vibrations generated when one spindle operates on the other side There is an advantage in that the phenomenon transmitted to the spindle is reduced and the machining perfection of the workpiece is improved.

Description

Anti-vibration structure of CNC machine

The present invention relates to an anti-vibration structure for preventing vibrations generated in one spindle from being transmitted to the other spindle in the operation of a two-spindle machine tool equipped with two spindles.

As shown in FIG. 1 , a typical two-spindle machine tool transfers the material from the first spindle 10 and the second spindle 20 and the first spindle 10 to the second spindle 30 arranged symmetrically to each other. It consists of a gantry 30, an IN stocker for supplying the material, and an OUT stocker for storing the processed material.

According to this prior art, the material stored in the IN stocker is supplied to the first spindle 10 by the gantry 30, and after the supplied material is first processed in the first spindle 10, the gantry 30 again The material is transferred to the second spindle 20 by the and processed by the second spindle 20 is stored in the OUT stocker.

On the other hand, in this prior art, the first spindle 10 and the second spindle 20 are connected to each other, and the gantry 30 is the bed portion 12, 22 of each spindle 10, 20. ), since it is supported by the supports 14 and 24 fixed to It is transmitted to affect each spindle (10, 20).

Therefore, according to this prior art, there is a problem in that an unexpected failure factor occurs due to the influence of the vibration transmitted from the other spindle 20 with respect to the workpiece processed by the one spindle 10 .

The present invention is to solve the above problems, and at the same time, a gap is formed between the bed part and the support of each spindle and at the same time, a gap is also formed between each bed part of each spindle, so that vibration between each spindle during operation is prevented. An object of the present invention is to provide an anti-vibration structure for a two-spindle machine tool that can prevent transition.

In order to achieve the above object, the vibration transition prevention structure of a two-spindle machine tool according to the present invention provided to achieve the above object includes a first spindle and a second spindle arranged symmetrically to each other, and a gen for transferring a material from the first spindle to the second spindle. a tree, a first support fixed to the first spindle to support the gantry, and a second support fixed to the second spindle to support the gantry.

In addition, it is connected to the first support and comprises a side auxiliary beam fixed to the ground, wherein the first support is connected to the side auxiliary beam, the lower end of the support bracket portion of the upper surface of the bed of the first spindle and spaced apart to form a gap.

In addition, the second support is connected to the second support and may include a side auxiliary beam fixed to the ground, and the second support is connected to the side auxiliary beam with a support bracket at the lower end of the bed portion of the second spindle. It is spaced apart from the upper surface to form a gap.

In addition, the bed portion of the first spindle and the bed portion of the second spindle are spaced apart from each other to form a gap.

The present invention may include a support pad detachably attached to the bottom surface of the support bracket at the lower end of the first support and selectively interposed in the gap between the support bracket and the upper surface of the bed of the first spindle.

The present invention may include a support pad detachably attached to the bottom surface of the support bracket at the lower end of the second support and selectively interposed in the gap between the support bracket and the upper surface of the bed of the second spindle.

The present invention may include a gap plate selectively fitted in a gap between the bed portion of the first spindle and the bed portion of the second spindle, wherein the gap plate includes the bed portion of the first spindle and A plate portion having a thickness thinner than the width of the gap between the bed portions of the second spindle, and formed on the upper end of the plate portion, the thickness of which is greater than the width of the gap between the bed portion of the first spindle and the bed portion of the second spindle is made of a thick locking end.

According to the present invention, since the support for supporting each spindle is connected to the side auxiliary beam, a gap is formed between the support and the bed portion, and since a gap is also formed between the bed portions of both spindles, vibrations generated when one spindle operates on the other side There is an advantage in that the phenomenon transmitted to the spindle is reduced and the machining perfection of the workpiece is improved.

Figure 1: A view showing a state of transition of vibration of a conventional two-spindle machine tool
Figure 2: A view showing a state in which the side auxiliary beam is applied in the present invention
Figure 3: A view showing the form of a side auxiliary beam applied to the present invention
Figure 4: A view showing a vibration transition prevention state in a state where the side auxiliary beam is applied to the present invention
Figure 5: A view showing a structure in which a gap is formed between the bed portions of both spindles in the present invention
Figure 6: A view showing the configuration of the support pad applied to the present invention
Figure 7: A view showing a state in which the support pad is attached in the present invention
Figure 8: A view showing a state in which the gap plate is applied in the present invention
9 is a view showing the configuration of a gap plate applied to the present invention

Hereinafter, specific contents for carrying out the present invention will be described in detail with reference to FIGS. 2 to 9 .

The vibration transition prevention structure of a two-spindle machine tool according to the present invention includes a first spindle 10 and a second spindle 20 arranged symmetrically to each other as shown in FIG. 2 , and a second in the first spindle 10 . A gantry 30 for transferring the material to the spindle 20, and a first support 14 fixed to the first bed portion 12 of the first spindle 10 to support the gantry 30, , a second support 24 fixed to the second bed 22 of the second spindle 20 to support the gantry 30, and the first support 14 connected to and fixed to the ground It comprises a side auxiliary beam (40).

In the state where the first support 14 is connected to the side auxiliary beam 40, the lower end of the support portion 141 is spaced apart from the upper surface of the first bed portion 12 of the first spindle 10 to form a gap 14a. ) is configured to achieve

As shown in FIG. 3, the side auxiliary beam 40 is illustratively a pair of post parts 42 and 42, and a transverse part ( 44), and a side bracket part 421 connected to the support 14 is provided on the side of each of the holding parts 42 and 42, and the lower ends of the holding parts 42 and 42 are anchored to the ground. It may be of a structure in which the bottom bracket part 422 is formed.

According to the present invention, in a state in which the second support 24 is connected to the side auxiliary beam 40, the supporting part at the lower end thereof is spaced apart from the upper surface of the second bed part 24 of the second spindle 20 to form a gap. It can also be configured. (Drawing omitted)

In addition, the side auxiliary beam 40 may be configured to be connected to both the first support 14 and the second support 24 , and even in this case, the first support 14 and the second support 24 are the lower ends of the first support 14 and the second support 24 . The support portion is configured to be spaced apart from the upper surface of the first bed portion 12 of the first spindle 10 and the upper surface of the second bed portion 22 of the second spindle 20 to form a gap. (not shown)

And, according to the present invention, the first bed portion 12 of the first spindle 10 and the second bed portion 22 of the second spindle 20 are spaced apart from each other to form a gap 12a. (See Fig. 5)

The operation of the present invention will be described as follows.

First, as shown in FIG. 4 , when the side auxiliary beam 40 is connected to the first support 12 , the first support 12 and the first bed portion 14 of the first spindle 10 . Since the are spaced apart, the vibration generated during operation of the first spindle 10 is not directly transmitted from the first bed 14 to the first support 12 .

Accordingly, the vibration generated in the first spindle 10 is transmitted to the second spindle 20 through the first support 14 and the gantry 30 to affect the operation of the second spindle 20 . this will be greatly reduced.

Similarly, when the side auxiliary beam 40 is connected to the second support 24 , the second support 24 and the second bed portion 24 of the second spindle 20 are spaced apart from each other. Vibration generated during the operation of the spindle 20 is not directly transmitted from the second bed part 22 to the second support 24 , and the vibration generated in the second spindle 20 is generated by the first spindle 10 . The phenomenon that affects the operation is greatly reduced. (Drawing omitted)

When the side auxiliary beam 40 is connected to both the first support 14 and the second support 24, the vibrations generated during the operation of each spindle 10 and 20 each spindle 10 ( 20) The phenomenon of mutual transmission is greatly reduced. (Drawing omitted)

Therefore, in the present invention, as a result, it can be seen that the configuration in which the side auxiliary beam 40 is connected to both the first support 14 and the second support 24 has the greatest vibration reduction effect.

However, when the side auxiliary beams 40 are connected to the supports 14 and 24 on both sides, the cost of manufacturing the device as a whole increases, so that vibration may occur in accordance with the operating characteristics of the spindles 10 and 20 When the side auxiliary beam 40 is connected only to the support 14 of any one of the spindles 10 with a large factor, an effective vibration transition prevention effect can be obtained while minimizing a cost increase factor.

In the present invention as described above, the side auxiliary beam 40 is applied after being transported and installed to a place of use after the production of the machine tool is completed, so as to prevent the vibration generated during operation of the machine tool from being transferred. do.

In addition, according to the present invention, as shown in FIG. 5 , a gap 12a is formed between the first bed portion 12 of the first spindle 10 and the second bed portion 22 of the second spindle 20 . Vibration transmitted between the two bed portions 12 and 22 is also reduced.

On the other hand, in the present invention, when the side auxiliary beam 40 is connected to the first support 14 as shown in FIG. 6 , the support pad on the bottom surface of the support part 141 at the lower end of the first support 14 ( 14 ). 5) can be detachably attached by a bolt coupling method, etc.

7, the support pad 5 is applied after the machine tool is manufactured and serves to support the support 14 in the process of being transported to the place of use, and is removed after the machine tool is installed.

In addition, according to the present invention, as shown in FIGS. 8 and 9, the gap between the first bed portion 12 of the first spindle 10 and the second bed portion 22 of the second spindle 20 ( A gap plate 50 may be fitted to 12a), wherein the gap plate 50 includes the first bed 12 of the first spindle 10 and the second of the second spindle 20 . A plate portion 52 having a thickness thinner than the width of the gap 12a between the bed portions 22, and formed on the upper end of the plate portion 52, and having a thickness thicker than the width of the gap 12a end 54 .

The gap plate 50 is applied after the machine tool is manufactured, and in the process of being transported to the place of use, the plate part 52 is a gap 12a between the bed parts 12 and 22 of each of the spindles 10 and 20. ) to prevent a collision between the bed parts 12 and 22 due to the gap 12a in the process of transporting the machine tool, and is removed after the machine tool installation is complete. do.

10: first spindle 12: first bed portion
14: first support 30: gantry
40: side auxiliary beam 50: gap plate

Claims (7)

a first spindle disposed symmetrically with each other and having a first bed portion and a second spindle having a second bed portion;
a gantry for transferring the material from the first spindle to the second spindle;
a first support fixed to the first spindle to support the gantry;
A second support fixed to the second spindle to support the gantry
In a two-spindle machine tool comprising a,

It is connected to the first support and consists of a side auxiliary beam fixed to the ground,
The first support is spaced apart from the upper surface of the first bed portion of the first spindle to form a gap at the lower end of the support in a state in which it is connected to the side auxiliary beam
Vibration transfer prevention structure of a 2-spindle machine tool, characterized by
According to claim 1,
It is connected to the second support and consists of a side auxiliary beam fixed to the ground,
In a state in which the second support is connected to the side auxiliary beam, the lower end of the support is spaced apart from the upper surface of the second bed of the second spindle to form a gap
Vibration transfer prevention structure of a 2-spindle machine tool, characterized by
3. The method of claim 2,
The first bed portion of the first spindle and the second bed portion of the second spindle are spaced apart from each other to form a gap
Vibration transfer prevention structure of a 2-spindle machine tool, characterized by
3. The method of claim 2,
A two-spindle machine tool comprising a support pad detachably attached to the bottom surface of the support bracket part of the lower end of the first support and selectively interposed in the gap between the support bracket part and the upper surface of the first bed part of the first spindle Anti-vibration structure.
5. The method of claim 4,
Vibration transition of a two-spindle machine tool comprising a support pad detachably attached to the bottom surface of the support part of the lower end of the second support and selectively interposed in the gap between the support part and the upper surface of the second bed part of the second spindle prevention structure. 4. The method of claim 3,
and a gap plate selectively fitted in a gap between the first bed portion of the first spindle and the second bed portion of the second spindle.
Vibration transfer prevention structure of a 2-spindle machine tool, characterized by
7. The method of claim 6, wherein the gap plate is
a plate part whose thickness is thinner than the width of the gap between the second bed part of the first spindle and the second bed part of the second spindle;
A locking end formed at the upper end of the plate portion and having a thickness greater than the width of the gap
Vibration transfer prevention structure of a two-spindle machine tool, characterized in that consisting of.

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